Insights on mauritiana-like elements diversity in Mayetiola destructor and M. hordei (Diptera: Cecidomyiidae).

Mariner-like elements (MLEs) are class II transposons belonging to the Tc1-mariner family that have successfully invaded many insect genomes. In the current study, the availability of the Hessian fly, Mayetiola destructor, genome has enabled us to perform in silico analysis of MLEs using a previously described mariner element (Desmar1) belonging to the mauritiana subfamily. Eighteen mauritiana-like elements were detected and clustered into three main groups: Desmar1-like, MauCons1, and MauCons2. Subsequently, in vitro analysis was carried out to investigate mauritiana-like elements in M. destructor as well as in Mayetiola hordei using primers designed from TIRs of previously identified MLEs. PCR amplifications were successful, and a total of 12 and 17 mauritiana-like elements were detected in M. destructor and M. hordei, respectively. Sequence analyses of mauritiana-like elements obtained in silico and in vitro have shown that MauCons1 and MauCons2 elements share low similarity with Desmar1 ranging from 50% to 55%, suggesting that different groups under the mauritiana subfamily have invaded the genomes of M. destructor and M. hordei. These groups were likely inherited by vertical transmission, which subsequently underwent different evolutionary histories. This work describes new mauritiana-like elements in M. destructor that are distinct from the previously discovered Desmar1 and provides the first evidence of MLEs belonging to the mauritiana subfamily in M. hordei.

Chloroplastic and nuclear diversity of endemic Prunus armeniaca L. species in the oasis agroecosystems.

Tunisia is characterized by the presence of specific seed-propagated apricot (Prunus armeniaca L.) material which is found in the oasis agroecosystems. In order to highlight the genetic diversity, population structure, and demographic history of this germplasm, 33 apricot accessions collected from six different oasis regions in southwestern Tunisia were genotyped using 24 microsatellite markers. A total number of 111 alleles was detected with an average of 4.62 alleles per locus. Bayesian model-based clustering analysis indicated four subdivisions within the collection sampled that corresponded mainly to the geographic origin of the material. The analysis of the 33 accessions using chloroplast markers allowed the identification of 32 haplotypes. Overall, the present study highlighted the high Tunisian apricot's diversity in the traditional oasis agroecosystems with low genetic differentiation. Understanding the structure of seed-propagated apricot collection is crucial for managing collections in regard to adaptive traits for Arid and Saharan climates as well as for identifying interesting genotypes that can be integrated into international coordinated actions of breeding programs.